Geometric-progression-free sets over quadratic number fields

In Ramsey theory one wishes to know how large a collection of objects can be while avoiding a particular substructure. A problem of recent interest has been to study how large subsets of the natural numbers can be while avoiding three-term geometric progressions. Building on recent progress on this problem, we consider the analogous problem over quadratic number fields. We first construct high-density subsets of the algebraic integers of an imaginary quadratic number field that avoid three-term geometric progressions. When unique factorization fails, or over a real quadratic number field, we instead look at subsets of ideals of the ring of integers. Our approach here is to construct sets ‘greedily’, a generalization of the greedy set of rational integers considered by Rankin. We then describe the densities of these sets in terms of values of the Dedekind zeta function. Next, we consider geometric-progression-free sets with large upper density. We generalize an argument by Riddell to obtain upper bounds for the upper density of geometric-progression-free subsets, and construct sets avoiding geometric progressions with high upper density to obtain lower bounds for the supremum of the upper density of all such subsets. Both arguments depend critically on the elements with small norm in the ring of integers.

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A Unit Norm Conjecture for Some Real Quadratic Number Fields: A Preliminary Heuristic Investigation

Journal of Advances in Mathematics and Computer Science ◽

10.9734/jamcs/2020/v35i330258 ◽

2020 ◽

pp. 46-50

Author(s):

Elliot Benjamin

Keyword(s):

Probability Density ◽

Number Field ◽

Number Fields ◽

Quadratic Number ◽

Quadratic Number Field ◽

Kronecker Symbol ◽

Theoretical Assumptions ◽

Quadratic Number Fields ◽

Real Quadratic ◽

Unit Norm

In this paper we make a conjecture about the norm of the fundamental unit, N(e), of some real quadratic number fields that have the form k = Q(√(p1.p2) where p1 and p2 are distinct primes such that pi = 2 or pi ≡ 1 mod 4, i = 1, 2. Our conjecture involves the case where the Kronecker symbol (p1/p2) = 1 and the biquadratic residue symbols (p1/p2)4 = (p2/p1)4 = 1, and is based upon Stevenhagen’s conjecture that if k = Q(√(p1.p2) is any real quadratic number field as above, then P(N(e) = -1)) = 2/3, i.e., the probability density that N(e) = -1 is 2/3. Given Stevenhagen’s conjecture and some theoretical assumptions about the probability density of the Kronecker symbols and biquadratic residue symbols, we establish that if k is as above with (p1/p2) = (p1/p2)4 = (p2/p1)4 = 1, then P(N(e) = -1)) = 1/3, and we support our conjecture with some preliminary heuristic data.

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The lattice of primary ideals of orders in quadratic number fields

International Journal of Number Theory ◽

10.1142/s1793042117500737 ◽

2016 ◽

Vol 12 (07) ◽

pp. 2025-2040 ◽

Cited By ~ 1

Author(s):

Giulio Peruginelli ◽

Paolo Zanardo

Keyword(s):

Prime Ideal ◽

Prime Number ◽

Number Field ◽

Number Fields ◽

Quadratic Number ◽

Quadratic Number Field ◽

Ring Of Integers ◽

The Core ◽

Number Formula ◽

Primary Ideals

Let [Formula: see text] be an order in a quadratic number field [Formula: see text] with ring of integers [Formula: see text], such that the conductor [Formula: see text] is a prime ideal of [Formula: see text], where [Formula: see text] is a prime. We give a complete description of the [Formula: see text]-primary ideals of [Formula: see text]. They form a lattice with a particular structure by layers; the first layer, which is the core of the lattice, consists of those [Formula: see text]-primary ideals not contained in [Formula: see text]. We get three different cases, according to whether the prime number [Formula: see text] is split, inert or ramified in [Formula: see text].

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On the Hilbert 2-class field of some quadratic number fields

International Journal of Number Theory ◽

10.1142/s179304211950043x ◽

2019 ◽

Vol 15 (04) ◽

pp. 807-824 ◽

Cited By ~ 1

Author(s):

Abdelmalek Azizi ◽

Mohammed Rezzougui ◽

Mohammed Taous ◽

Abdelkader Zekhnini

Keyword(s):

Number Field ◽

Class Group ◽

Number Fields ◽

Quadratic Number ◽

Quadratic Number Field ◽

Class Field ◽

Quadratic Number Fields

In this paper, we investigate the cyclicity of the [Formula: see text]-class group of the first Hilbert [Formula: see text]-class field of some quadratic number field whose discriminant is not a sum of two squares. For this, let [Formula: see text] be different prime integers. Put [Formula: see text], and denote by [Formula: see text] its [Formula: see text]-class group and by [Formula: see text] (respectively [Formula: see text]) its first (respectively second) Hilbert [Formula: see text]-class field. Then, we are interested in studying the metacyclicity of [Formula: see text] and the cyclicity of [Formula: see text] whenever the [Formula: see text]-rank of [Formula: see text] is [Formula: see text].

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On unramified Am-extensions of quadratic number fields

Glasgow Mathematical Journal ◽

10.1017/s0017089500006054 ◽

1985 ◽

Vol 27 ◽

pp. 31-37 ◽

Cited By ~ 3

Author(s):

J. Elstrodt ◽

F. Grunewald ◽

J. Mennicke

Keyword(s):

Number Field ◽

Automorphic Forms ◽

Number Fields ◽

Quadratic Number ◽

Quadratic Number Field ◽

Quadratic Extensions ◽

Rings Of Integers ◽

Quadratic Number Fields ◽

Real Quadratic

Number fields such as described in the title play a rôle in the study of Artin L-functions and automorphic forms for the groups SL2 over rings of integers in quadratic extensions of ℚ. They are also of some interest on their own. We have not found many examples in the literature. Lang [4] mentions an unramified A5-extension of a real quadratic number field which is due to E. Artin.

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Hyperbolic tessellations and generators of for imaginary quadratic fields

Forum of Mathematics Sigma ◽

10.1017/fms.2021.9 ◽

2021 ◽

Vol 9 ◽

Author(s):

David Burns ◽

Rob de Jeu ◽

Herbert Gangl ◽

Alexander D. Rahm ◽

Dan Yasaki

Keyword(s):

Number Field ◽

Number Fields ◽

Quadratic Fields ◽

Quadratic Number ◽

Imaginary Quadratic Fields ◽

Quadratic Number Fields ◽

Formula Group ◽

Imaginary Quadratic Number ◽

Direct Calculations

Abstract We develop methods for constructing explicit generators, modulo torsion, of the $K_3$ -groups of imaginary quadratic number fields. These methods are based on either tessellations of hyperbolic $3$ -space or on direct calculations in suitable pre-Bloch groups and lead to the very first proven examples of explicit generators, modulo torsion, of any infinite $K_3$ -group of a number field. As part of this approach, we make several improvements to the theory of Bloch groups for $ K_3 $ of any field, predict the precise power of $2$ that should occur in the Lichtenbaum conjecture at $ -1 $ and prove that this prediction is valid for all abelian number fields.

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Higher genus theory

International Mathematics Research Notices ◽

10.1093/imrn/rnaa196 ◽

2020 ◽

Author(s):

Peter Koymans ◽

Carlo Pagano

Keyword(s):

Number Field ◽

Quadratic Forms ◽

Class Group ◽

Quadratic Extension ◽

Number Fields ◽

Explicit Description ◽

Quadratic Number ◽

Quadratic Number Field ◽

Genus Theory ◽

Narrow Class

Abstract In $1801$, Gauss found an explicit description, in the language of binary quadratic forms, for the $2$-torsion of the narrow class group and dual narrow class group of a quadratic number field. This is now known as Gauss’s genus theory. In this paper, we extend Gauss’s work to the setting of multi-quadratic number fields. To this end, we introduce and parametrize the categories of expansion groups and expansion Lie algebras, giving an explicit description for the universal objects of these categories. This description is inspired by the ideas of Smith [ 16] in his recent breakthrough on Goldfeld’s conjecture and the Cohen–Lenstra conjectures. Our main result shows that the maximal unramified multi-quadratic extension $L$ of a multi-quadratic number field $K$ can be reconstructed from the set of generalized governing expansions supported in the set of primes that ramify in $K$. This provides a recursive description for the group $\textrm{Gal}(L/\mathbb{Q})$ and a systematic procedure to construct the field $L$. A special case of our main result gives an upper bound for the size of $\textrm{Cl}^{+}(K)[2]$.

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Class group of the group ring of a cyclic group of order p2 over the ring of integers in a quadratic number field

Journal of Algebra ◽

10.1016/0021-8693(86)90104-3 ◽

1986 ◽

Vol 101 (1) ◽

pp. 151-165

Author(s):

Soroosh Homayouni

Keyword(s):

Number Field ◽

Cyclic Group ◽

Group Ring ◽

Class Group ◽

Quadratic Number ◽

Quadratic Number Field ◽

Ring Of Integers

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RAY CLASS GROUPS OF QUADRATIC AND CYCLOTOMIC FIELDS

International Journal of Number Theory ◽

10.1142/s1793042110003447 ◽

2010 ◽

Vol 06 (05) ◽

pp. 1169-1182

Author(s):

JING LONG HOELSCHER

Keyword(s):

Number Field ◽

Number Fields ◽

Quadratic Number ◽

Class Groups ◽

Quadratic Number Field ◽

Cyclotomic Number ◽

Class Field ◽

Ray Class Field ◽

Real Quadratic ◽

Mod P

This paper studies Galois extensions over real quadratic number fields or cyclotomic number fields ramified only at one prime. In both cases, the ray class groups are computed, and they give restrictions on the finite groups that can occur as such Galois groups. Let [Formula: see text] be a real quadratic number field with a prime P lying above p in ℚ. If p splits in K/ℚ and p does not divide the big class number of K, then any pro-p extension of K ramified only at P is finite cyclic. If p is inert in K/ℚ, then there exist infinite extensions of K ramified only at P. Furthermore, for big enough integer k, the ray class field (mod Pk+1) is obtained from the ray class field (mod Pk) by adjoining ζpk+1. In the case of a regular cyclotomic number field K = ℚ(ζp), the explicit structure of ray class groups (mod Pk) is given for any positive integer k, where P is the unique prime in K above p.

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